CN111957752A - Production method for eliminating bright band and additional wave shape defects on surface of hot-rolled low-carbon mild steel - Google Patents

Abstract

The invention discloses a production method for eliminating bright strips and additional wave-shaped defects on the surface of hot-rolled low-carbon mild steel, which is characterized in that hot-rolled low-carbon mild steel is obtained by slab continuous casting, heating, rough rolling, finish rolling, laminar cooling, coiling and leveling warehousing; in the method, the elimination of bright strip and additional wave shape is realized through three control stages of a descaling control stage before finish rolling, a local high point control stage in the middle of the section of finish rolled strip steel and a coiling pinch roll and tension control stage; in the strip steel coiling stage, the coiling unit tension and the pinch roll pressure are reduced when the strip steel is stably coiled, so that the incidence rate of low-carbon mild steel bright strips is finally reduced, the defect of the bright strips accompanying middle waves is eliminated or reduced to a certain extent, and the loss caused by the cutting loss and repeated leveling of the steel coil is reduced.

Description

Production method for eliminating bright band and additional wave shape defects on surface of hot-rolled low-carbon mild steel

Technical Field

The invention relates to the field of manufacturing of hot-rolled strip steel in ferrous metallurgy, in particular to a production method for eliminating bright strip and additional wave defects on the surface of hot-rolled low-carbon mild steel.

Background

The surface quality and the plate shape quality of the hot-rolled strip steel are important indexes for measuring the product quality, and the hot-rolled strip steel also has very important influence on the finished product quality of downstream processes and the production process. In the production process of the hot-rolled low-carbon mild steel, bright strips and additional wave-shaped defects are easy to appear on the surface of the strip steel, as shown in figures 1-2. Such defects are particularly acute when the product is thin (1.4 mm or less) in thickness. The serious bright band and the accompanying additional wave-shaped defects can cause large cutting loss, lead the rework rate of the leveling process to be high and bring very large economic loss.

The surface bright band and the accompanying additional wave shape are the common defects on the surface of the hot-rolled low-carbon steel, and the main macroscopic manifestations of the defects are as follows: after the steel coil is uncoiled, strip bright bands exist in the range of 0-200 mm of the central line of the width of the steel coil, the surface smoothness of the bright band parts is obviously higher than that of other parts, the number of the bright bands is more than 1, and the bright bands are occasionally seen. The width of a single bright band is generally 40-80 mm, the length of the bright band is generally within the length range of 100m at the tail of the steel coil, and partial steel coils also have full-length bright bands. In addition, there are two important concomitant phenomena of bright band defects:

(1) the bright band part is often accompanied by additional local wave shape defects, and the thinner the general band steel specification is, the more serious the wave shape is;

(2) the steel coil is coiled and then bulges at the bright belt part. In fact, the bright band defect on the surface of the strip steel does not lead to the quality judgment of the strip steel, and the additional wave-shaped defect associated with the bright band is the main reason for cutting loss and leveling rework.

The invention discloses a method for eliminating bright bands on the surface of strip steel, which is characterized in that descaling passes and descaling water pressures of rough rolling and finish rolling procedures are adjusted, and the defect of bright bands on the surface of the strip steel is overcome through reasonable optimization and adjustment of a hot rolling process. The patent considers that the scale is not removed completely to cause the iron sheet to be pressed into the pickling surface to form the bright band defect, and does not relate to the solution of the bright band and the additional wave-shaped defect of the hot rolling surface of the low-carbon mild steel.

Disclosure of Invention

The invention provides a production method for eliminating bright strip and additional wave defects on the surface of hot-rolled low-carbon mild steel, aiming at the bright strip and the additional wave defects generated on the surface of a steel coil in the production process of the low-carbon mild steel and based on the comprehensive control of local high-point control of the section of strip steel and pressure and tension control of a coiling pinch roll.

In order to achieve the aim, the invention designs a production method for eliminating bright strips and additional wave-shaped defects on the surface of hot-rolled low-carbon mild steel, which obtains the hot-rolled low-carbon mild steel through slab continuous casting, heating, rough rolling, finish rolling, laminar cooling, coiling and leveling warehousing; in the method, the elimination of bright strip and additional wave shape is realized through three control stages of a descaling control stage before finish rolling, a local high point control stage in the middle of the section of finish rolled strip steel and a coiling pinch roll and tension control stage; wherein the content of the first and second substances,

1) in the process of the descaling control stage before finish rolling:

the descaling pressure of the descaling box before finish rolling is 12-15 MPa, and the jet flow overlapping width of adjacent nozzles in the range of +/-400 mm of the center line of the descaling box is 10-15 mm; (ii) a

2) In the process of the control stage of the local high point in the middle of the section of the finish rolling strip steel:

the surface temperature difference of the strip steel in the width direction within the range of +/-200 mm of the central line of the strip steel is controlled to be less than or equal to 20 ℃; the tonnage of finish rolling F1 frame working roll is 3200-3600 tons, the tonnage of F2-F4 frame working roll is 1600-1800 tons, and the tonnage of F5-F7 frame working roll is 750-900 tons; the precision rolling F5-F7 frame working rolls adopt a uniform roll shifting mode, the roll shifting stroke is 50-80 mm, the roll shifting step length is 10-15 mm, and the roll shifting frequency is 1;

and the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is controlled to be H₀≤10μm；

3) In the process of coiling pinch roll and tension control stage:

and when the strip steel is stably coiled, controlling the coiling unit tension Tu to be 20-30 MPa and the pinch roll pressure P to be less than or equal to 30 KN.

Further, in the process of the control stage of the local high point in the middle of the section of the finish-rolled strip steel:

the tonnage of finish rolling F1 machine frame working roll is 3200-3400 tons, the tonnage of F2-F4 machine frame working roll is 1600-1700 tons, and the tonnage of F5-F7 machine frame working roll is 750-850 tons.

And further, in the process of the control stage of the local high point in the middle of the section of the finish rolling strip steel: the maximum uneven wear (the difference between the actual wear and the normal wear) of the working rolls in the range of +/-200 mm of the width center line of the finish rolling F5-F7 is controlled to be Hw less than or equal to 20 mu m.

And further, when the thickness of the strip steel is less than or equal to 1.2mm, the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is controlled to be H₀≤6μm；

Still further, in the coiling pinch roll and tension control stage process: the pressure P of the pinch roll is less than or equal to 20 KN.

Further, the chemical components for eliminating the hot-rolled low-carbon mild steel comprise the following components in percentage by weight: 0.01-0.06%, Si is less than or equal to 0.03%, Mn: 0.1-0.5%, P is less than or equal to 0.03%, S is less than or equal to 0.025%, N is less than or equal to 0.008%, Als: 0.02-0.06% and B: 0.0008 to 0.0025; the balance of Fe and inevitable impurities.

The technical principle and the reason of the method of the invention are as follows:

as shown in fig. 3: the main production flow of hot-rolled low-carbon mild steel is slab continuous casting → heating → (rough rolling) → finish rolling → laminar cooling → coiling → leveling and warehousing. As shown in fig. 4: when hot-rolled strip steel is produced, if certain hot-rolled key process parameters are not well controlled, local high points deviating from an ideal thickness profile (nominal thickness) may exist on the section curve of the actual thickness of the strip steel after the strip steel is taken out of a finishing mill. Research shows that certain proportion of bright band and additional wave-shaped defects on the surface of the low-carbon mild steel are caused by local high points of the strip steel. There may be two mechanisms of formation:

the first mechanism is: after the strip steel enters the pinch roll of the coiling machine, because the strip steel has certain convexity, a local high point area in the middle of the width of the strip steel is firstly contacted with the pinch roll, and the local high point area can be plastically flattened and longitudinally extended under the action of local stress formed by the resultant force of the pressure and the coiling tension of the pinch roll. According to the theory of plate shape and flatness, the additional extension of the local high point area will form the middle wave, and the severity of the middle wave is positively correlated with the rolling reduction of the local high point area. Meanwhile, the relative friction between the strip steel and the pinch roll forms a bright strip (figure 5 a);

the second mechanism is: under the action of pinch roll pressure and coiling tension, the strip steel is elastically flattened and rubbed in a local high-point area in the middle of the strip steel to form a bright strip, but the strip steel cannot form a middle wave shape; in the local high point area, after the steel coil is coiled, the radial thickness is accumulated and superposed to form a steel coil outer ring bulge (Build-up), so that radial and circumferential stress concentration is caused, and the equivalent stress is increased suddenly. When the stress exceeds the yield strength of the strip steel, the middle wave shape can appear in the bulging area due to the change of mechanical conditions during uncoiling. Because the reduction rate is less in the steel coil flattening process, local high points can be reserved to a greater extent, and therefore the wave-shaped defects are left to the flattened steel coil, namely the flattening process is difficult to eliminate the wave-shaped defects (fig. 5 b).

In the two mechanisms, the bright band and the additional wave-shaped defects on the surface of the low-carbon mild steel are closely related to the middle local high point of the profile of the section of the strip steel. The reason for forming the middle local high point of the section profile of the strip steel can be as follows:

(1) uneven wear of the finish rolling work rolls;

(2) differential thermal expansion of the finish rolling work rolls.

If the middle part of the finish rolling working roll has uneven wear, metal easily flows to the excessively worn part of the middle part of the roll during the rolling of the strip steel, so that a local high point is formed. The possible cause of such wear of the rolls is uneven cooling of the upper and lower surfaces of the strip during high pressure descaling. The surface of the strip steel after descaling is in an obvious strip shape, and the grain sizes of different strips are obviously different. For example, the crystal grain size ranges from 1700 to 2000 crystal grains per square millimeter in the low temperature zone, and from 1000 to 1300 crystal grains per square millimeter in the high temperature zone. Fine grain strength is high and therefore provides greater resistance to deformation than coarse grain strip and therefore more severe wear to the work rolls.

Differential thermal expansion of the finish rolling work rolls is generally caused by differential cooling of the work rolls.

Therefore, in order to control the middle local high point of the section profile of the strip steel, the descaling pressure is reduced as much as possible under the condition of ensuring the descaling quality in the finish rolling stage. The descaling pressure of the descaling box before finish rolling is controlled to be 12-15 MPa, and the jet flow overlapping width of adjacent nozzles of the descaling box is 10-15 mm (as shown in figure 6). The method aims to reduce the influence of descaling pressure and water flow in an overlapping area on the surface temperature nonuniformity of the strip steel, so that the temperature difference of the surface of the strip steel within the range of +/-200 mm of the width center line of the strip steel before finish rolling is controlled to be less than or equal to 20 ℃.

The method is characterized in that the rolling tonnage of a working roll of a finishing mill frame is correspondingly limited, a uniform roll shifting mode is adopted for the working rolls of the finishing mill frames F5-F7, the roll shifting stroke is controlled to be 50-80 mm, the roll shifting step length is 10-15 mm, and the roll shifting frequency is 1, so that the finishing rolling working roll is uniformly worn in service, and the maximum uneven wear (the difference between the actual wear and the normal wear) of the finishing rolling F5-F7 working roll within the range of +/-200 mm of the width center line is controlled to be Hw less than or equal to 20 mu m.

In the finish rolling stage, the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is finally controlled to be H₀Less than or equal to 10 mu m; for steel coils with the thickness of less than or equal to 1.2mm and the width central line +/-200 mm of the strip steel, the height of the local high point is controlled to be H₀≤6μm。

Stable strip steel coiling stageAnd the strip steel is acted by the pressure P of the pinch roll in the thickness direction and longitudinally acted by the tension T between the rolling mill and the coiling machine. Because the middle part of the section of the strip steel has a local high point, when the strip steel enters the pinch roll, the strip steel is firstly contacted with the pinch roll at the local high point (as shown in figure 7). Therefore, the plane comprehensive stress K of the strip steel in the local high point area is as follows: k is P/dL_p+ T/bh. Wherein b is the width of the strip steel, d is the width of the contact area of the pinch roll and the local high point, and L_pThe longitudinal contact length of the pinch roll and the strip steel is shown, and h is the thickness of the strip steel. When K exceeds the yield limit of the strip steel, namely: k is P/dLp + T/bh is more than or equal to sigma_sWhen the hot rolling strip is in use, the local high points are plastically flattened, so that the hot strip is excessively extended to form a wave shape and slides in a friction manner relative to the pinch roll to form the hot strip. Therefore, in the coiling pinch roll and tension control stage, the coiling unit tension (controlled to be Tu 20-30 MPa) when the strip is stably coiled is reduced, and the pinch roll pressure (controlled to be P less than or equal to 30KN, preferably P less than or equal to 20KN) is reduced, so that the bright strip and additional wave form incidence rate is reduced or the defect severity is reduced.

The reason why the control method of the present invention limits the chemical composition of the mild low carbon steel is that the steel grade having the composition has a high-temperature yield limit σ_sLower, easily deformed.

The invention has the beneficial effects that:

according to the method for controlling the bright strip and the additional wave-shaped defects on the surface of the low-carbon mild steel, the descaling pressure and the jet flow overlapping quantity width of adjacent descaling nozzles are controlled before finish rolling in the finish rolling stage, so that the influence of the descaling pressure and the water flow in an overlapping area on the surface temperature nonuniformity of the strip steel is reduced; correspondingly limiting the rolling tonnage of the working roll of the finishing mill frame and adjusting the roll shifting process of the working rolls of the finishing mill frames F5-F7 to ensure that the finishing mill working rolls are uniformly worn in service, thereby controlling the height of a local high point within the range of +/-200 mm of the width center line of the strip steel. In addition, in the strip steel coiling stage, the coiling unit tension and the pinch roll pressure are reduced when strip steel is stably coiled, so that the incidence rate of low-carbon soft steel bright strips is finally reduced, the defect of accompanying middle waves of the bright strips is eliminated or reduced to a certain extent, and the loss caused by cutting loss and repeated leveling of the strip steel is reduced.

Drawings

FIG. 1 is a photograph of a bright band on the surface of the low-carbon mild steel and a defect form of an additional wave shape;

FIG. 2 is a schematic view of the shape of the bright band and the additional wave-shaped defects on the surface of the low-carbon mild steel according to the present invention;

FIG. 3 is a schematic view of a hot rolled low carbon mild steel production process based on a thin slab CSP process,

wherein, 1 is slab continuous casting, 2 is soaking furnace heating, 3 is finish rolling, 3a is a descaling box before finish rolling, 4 is strip steel laminar cooling, 5 is strip steel coiling, 5a is a coiling pinch roll, and 6 is strip steel leveling;

FIG. 4 is a schematic view of a cross-sectional curve and a local high point of a hot rolled strip, wherein H0 is the height of the local high point in the middle of the strip;

FIG. 5 is a schematic diagram of a possible forming mechanism of the bright band and the additional wave-shaped defects on the surface of the mild low-carbon steel, wherein a is a forming mechanism 1, and b is a forming mechanism 2;

FIG. 6 is a schematic diagram showing the arrangement of two adjacent headers of the descaling box before finish rolling, wherein D is the overlapping amount of jet flows of the nozzles;

FIG. 7 is a schematic view showing the analysis of the force applied to the strip during the coiling of the strip.

Detailed Description

The present invention is described in further detail below with reference to specific examples so as to be understood by those skilled in the art.

The invention relates to a production method for eliminating bright strips and additional wave-shaped defects on the surface of hot-rolled low-carbon mild steel, which is characterized in that the hot-rolled low-carbon mild steel is obtained by slab continuous casting, heating, rough rolling, finish rolling, laminar cooling, coiling and leveling warehousing; in the method, the elimination of bright strip and additional wave shape is realized through three control stages of a descaling control stage before finish rolling, a local high point control stage in the middle of the section of finish rolled strip steel and a coiling pinch roll and tension control stage; wherein the content of the first and second substances,

1) in the process of the descaling control stage before finish rolling:

the descaling pressure of the descaling box before finish rolling is 12-15 MPa, and the jet flow overlapping width of adjacent nozzles in the range of +/-400 mm of the center line of the descaling box is 10-15 mm; (ii) a

2) In the process of the control stage of the local high point in the middle of the section of the finish rolling strip steel:

the surface temperature difference of the strip steel in the width direction within the range of +/-200 mm of the central line of the strip steel is controlled to be less than or equal to 20 ℃; the tonnage of finish rolling F1 frame working roll is 3200-3600 tons, the tonnage of F2-F4 frame working roll is 1600-1800 tons, and the tonnage of F5-F7 frame working roll is 750-900 tons; the precision rolling F5-F7 frame working rolls adopt a uniform roll shifting mode, the roll shifting stroke is 50-80 mm, the roll shifting step length is 10-15 mm, and the roll shifting frequency is 1;

and the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is controlled to be H₀≤10μm；

3) In the process of coiling pinch roll and tension control stage:

and when the strip steel is stably coiled, controlling the coiling unit tension Tu to be 20-30 MPa and the pinch roll pressure P to be less than or equal to 30 KN.

The actual operation is carried out based on the method:

example 1

Hot-rolled low-carbon mild steel (SPHC steel), the thickness specification of the strip steel is 1.0mm to 3.0mm, the chemical composition weight percentage (wt.%) of the strip steel is shown in table 1, and the balance is Fe and unavoidable impurities. The relevant process of the strip steel is shown in tables 2a, 2b and 2 c.

Table 1: chemical composition of strip steel (wt.%)

	C	Si	Mn	P	S	N	B	Alt
									Example 1	0.031	0.010	0.22	0.015	0.006	0.005	0.0012	0.04
Comparative example	0.035	0.011	0.21	0.013	0.006	0.006	0.0011	0.034

TABLE 2a

TABLE 2b

TABLE 2c

Table 3 below shows the bright band and additional waveform control results of example 1 and comparison with the comparative example.

Table 3: effects of the implementation

Example 2

The hot-rolled low-carbon mild steel (SAE1006 steel) has a thickness specification of 1.0mm to 3.5mm, chemical components in percentage by weight (wt.%) of the strip are shown in Table 4, and the balance of Fe and inevitable impurities. The relevant process for the strip is shown in tables 5a, 5b, 5 c.

Table 4: chemical composition of strip steel (wt.%)

	C	Si	Mn	P	S	N	B	Alt
									Example 2	0.051	0.02	0.32	0.02	0.006	0.005	0.0008	0.04
Comparative example	0.045	0.021	0.31	0.02	0.006	0.006	0.0011	0.034

TABLE 5a

TABLE 5b

TABLE 5c

Table 6 below shows the bright band and additional waveform control results of example 2 and comparison to the comparative example.

Table 6: effects of the implementation

In the embodiment, the descaling pressure and the jet flow overlapping quantity width of the adjacent descaling nozzles are controlled before finish rolling in the finish rolling stage, so that the influence of the descaling pressure and the water flow in the overlapping area on the surface temperature nonuniformity of the strip steel is reduced; the rolling tonnage of the working roll of the finishing mill frame is correspondingly limited, and the roll shifting process of the working roll of the finishing mill frame F5-F7 is adjusted to ensure that the finishing mill working roll generates uniform abrasion in service, so that the height of a local high point within the range of +/-200 mm of the width center line of the strip steel is controlled. In addition, in the strip steel coiling stage, the coiling unit tension and the pinch roll pressure are reduced when strip steel is stably coiled, so that the incidence rate of low-carbon soft steel bright strips is finally reduced, the defect of accompanying middle waves of the bright strips is eliminated or reduced to a certain extent, and the loss caused by cutting loss and repeated leveling of the strip steel is reduced.

Other parts not described in detail are prior art. Although the present invention has been described in detail with reference to the above embodiments, it is only a part of the embodiments of the present invention, not all of the embodiments, and other embodiments can be obtained without inventive step according to the embodiments, and the embodiments are within the scope of the present invention.

Claims (6)

1. A production method for eliminating bright strips and additional wave-shaped defects on the surface of hot-rolled low-carbon mild steel is characterized in that the hot-rolled low-carbon mild steel is obtained by slab continuous casting, heating, rough rolling, finish rolling, laminar cooling, coiling and leveling warehousing; the method is characterized in that: in the method, the elimination of bright strip and additional wave shape is realized through three control stages of a descaling control stage before finish rolling, a local high point control stage in the middle of the section of finish rolled strip steel and a coiling pinch roll and tension control stage; wherein the content of the first and second substances,

1) in the process of the descaling control stage before finish rolling:

the descaling pressure of the descaling box before finish rolling is 12-15 MPa, and the jet flow overlapping width of adjacent nozzles in the range of +/-400 mm of the center line of the descaling box is 10-15 mm; (ii) a

2) In the process of the control stage of the local high point in the middle of the section of the finish rolling strip steel:

the surface temperature difference of the strip steel in the width direction within the range of +/-200 mm of the central line of the strip steel is controlled to be less than or equal to 20 ℃; the tonnage of finish rolling F1 frame working roll is 3200-3600 tons, the tonnage of F2-F4 frame working roll is 1600-1800 tons, and the tonnage of F5-F7 frame working roll is 750-900 tons; the precision rolling F5-F7 frame working rolls adopt a uniform roll shifting mode, the roll shifting stroke is 50-80 mm, the roll shifting step length is 10-15 mm, and the roll shifting frequency is 1;

and the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is controlled to be H₀≤10μm；

3) In the process of coiling pinch roll and tension control stage:

and when the strip steel is stably coiled, controlling the coiling unit tension Tu to be 20-30 MPa and the pinch roll pressure P to be less than or equal to 30 KN.

2. The production method for eliminating the bright band and the additional wave-shaped defects on the surface of the hot-rolled low-carbon mild steel according to claim 1, which is characterized by comprising the following steps of: the middle part of the section of the finish rolling strip steel is controlled at a local high point:

the tonnage of finish rolling F1 machine frame working roll is 3200-3400 tons, the tonnage of F2-F4 machine frame working roll is 1600-1700 tons, and the tonnage of F5-F7 machine frame working roll is 750-850 tons.

3. The production method for eliminating the bright band and the additional wave-shaped defects on the surface of the hot-rolled low-carbon mild steel according to claim 1, which is characterized by comprising the following steps of: the middle part of the section of the finish rolling strip steel is controlled at a local high point: the maximum uneven wear amount of the finish rolling F5-F7 working roll within the range of the width center line +/-200 mm is controlled to be Hw less than or equal to 20 mu m.

4. The method for eliminating the bright band and the additional wave-shaped defects on the surface of the hot-rolled low-carbon mild steel according to claim 1The production method is characterized in that: when the thickness of the strip steel is less than or equal to 1.2mm, the height of the local high point within the range of +/-200 mm of the width center line of the strip steel is controlled to be H₀≤6μm。

5. The production method for eliminating the bright band and the additional wave-shaped defects on the surface of the hot-rolled low-carbon mild steel according to claim 1, which is characterized by comprising the following steps of: and in the coiling pinch roll and tension control stage process: the pressure P of the pinch roll is less than or equal to 20 KN.

6. The production method for eliminating the bright band and the additional wave-shaped defects on the surface of the hot-rolled low-carbon mild steel according to claim 1, which is characterized by comprising the following steps of: the weight percentage of chemical components of the hot-rolled low-carbon mild steel is C: 0.01-0.06%, Si is less than or equal to 0.03%, Mn: 0.1-0.5%, P is less than or equal to 0.03%, S is less than or equal to 0.025%, N is less than or equal to 0.008%, Als: 0.02-0.06% and B: 0.0008 to 0.0025; the balance of Fe and inevitable impurities.

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